DE3135563C2 - Circuit arrangement for switching off a television receiver in the event of excessive anode high voltage - Google Patents

Abstract

The flyback pulse voltage developed across a winding (31e) of the flyback transformer of a television receiver is rectified (68) and filtered (69) in order to obtain a voltage representative of the ultor voltage of the picture tube. This representative voltage is applied to an input (emitter of 62) of a comparator (62). A voltage representative of the beam current, such as is available, for example, at the input of a beam current limiter (56), is applied to a filter (82). The output voltage of the filter, which represents the time integral of the voltage representative of the beam current, is applied to another input (98) of the comparator. If the voltage representative of the ultor voltage exceeds a threshold value which is different for different values of the filter output voltage, the comparator generates a switch-off signal which is used to switch off the normal playback operation of the television receiver. The information about the beam current at the filter output is used to increase the sensitivity of the comparator to an increase in the ultor voltage in the case of higher beam currents, which lead to the fear of stronger X-ray emissions from the picture tube, while unnecessary switching off of the playback mode at lower beam current values, where a larger increase in ultor voltage can be tolerated is prevented. The time constant of the filter (82) is in the case of ...

Description

characterized,
that the filter (82) of the beam current sensing circuit is designed with two different time constants having integrators (59, 79, 83 and 84, 86), and the time constant of the first integrator (59, 79, 83) is dimensioned so that the second measurement voltage (at circuit point D) short-term changes in the anode high voltage, which are reflected in the beam current, can follow, and that the second integrator (84, 86) via the switch (diode 45) that becomes conductive at high beam currents to the first integrator to increase the time constant of the Filters (82) is coupled.

2. Circuit arrangement according to claim 1, characterized in that the first integrator has a first capacitor (83) and that the second integrator contains a second capacitor (84) contains and that the switch (85) the second capacitor (84) in parallel with the first capacitor (83) couples when the second measurement voltage on the first capacitor (83) exceeds a predetermined amount.

3. Circuit arrangement according to claim 2, characterized in that the switch is a diode (85) which is connected in series with the second capacitor (84), and that this series connection is arranged parallel to the first capacitor (83).

4. Circuit arrangement according to claims 1 to 3, characterized in that the filter output voltage via a variable impedance (80) which has a first impedance value when the Filter output voltage below a pre- t> o of the correct amount, and which has a second impedance value when the output voltage above this predetermined amount is applied to the comparison circuit (transistor 62).

5. A circuit arrangement according to claim 4, DA t>^r> characterized by that the variable impedance comprises a parallel circuit of a resistor (78) and a diode (81).

6. Circuit arrangement according to claim 5, characterized in that the diode (81) is a Zener diode is

7. Circuit arrangement according to claim 1, characterized in that the time constant of the second integrator (84, 86) is a few hundred milliseconds and that the time constant of the first Integrator (59,79,83) is a few milliseconds.

8. Circuit arrangement according to claim 1, characterized in that the high-voltage generator contains an AC voltage source (33) and a transformer (31) which has a primary winding (3Ia) coupled to the AC voltage source (33) and a high-voltage winding coupled to a high-voltage circuit (at LJ) (3 \ d) for generating the anode voltage, and that a third winding (31e> of the transformer (31) supplies the first measurement voltage.

9. Circuit arrangement according to claim 8, characterized in that the third winding (3Ie,) of the transformer via a rectifier (68) and a filter (69) is coupled to the comparison circuit (Tr 62).

10. Circuit arrangement according to claims, characterized characterized in that the transformer is a flyback transformer (31) and that the AC voltage source a deflection generator (33) which applies a flyback pulse voltage to the primary winding (31a ^ of the flyback transformer sets.

11. Circuit arrangement according to claim 10, characterized in that the comparison circuit (Tr62) sends the switch-off signal to a holding circuit (99) coupled to the deflection generator (33), which is activated by the switch-off signal and blocks the deflection generator.

The invention relates to a circuit arrangement for switching off a television receiver as described in the preamble of claim 1 is required.

In a television picture display device, the high voltage potential is typically applied to the end anode of the picture tube a high DC voltage applied to an electron beam generated at the cathode of the picture tube to give a final acceleration towards the fluorescent screen. When the electron beam is on hits the phosphor particles of the screen, then these particles light up. The one from the fluorescent particles The amount of light emitted depends on the level of the acceleration potential at the end anode. Ie bigger this anode high voltage, the stronger the light emission of the phosphor for a given one Level of the input signal at the electrodes of the electron gun. So that the one on the fluorescent screen reproduced images appear with a relatively high brightness are relatively high anode high voltages he wishes. In a television receiver with a shadow mask color picture tube, the anode high voltage 30 kV.

Since the electron beams of a color picture tube are accelerated to a relatively high speed, before they hit the shadow mask and the! .fluorescent screen hit, the phosphor particles emit not only the desired light but also a certain amount of X-rays. Under normal operating conditions, almost all of the X-ray radiation emitted is from the glass

of the picture tube piston, of the front panel and of neighboring metallic structures such as, for. B. the magnetic Shielding absorbed. With normal anode high voltage and normal beam current, the Amount of X-rays emitted by the picture tube and neighboring structures is not absorbed, extremely little and therefore without any harmful influence on in the People nearby.

So that the television receiver under unwanted conditions does not emit excessive x-rays, came; inan a high-voltage protection circuit in the receiver provide that ensures an abnormal image is generated when the anode high voltage inadmissible values reached. There can be a characteristic curve for each television picture display device which is the relationship between the anode high voltage and the anode beam current and is known as the "isodose curve". An operation of the playback device with a high voltage in Area above the isodose curve should be avoided to ensure that people are present not be exposed to any noticeable X-rays.

The amount of x-rays emitted depends on the product (uf'fi) ¹ , where u is the anode high voltage, ι the beam current flowing out of the anode connection and m, π are positive numbers. Since the amount of X-ray emission increases with increasing beam current, the isodose curve generally deviates from a horizontal straight line, so that at higher beam current values the television receiver does not get a lower one. High-voltage values should be operated in order to place the operating points in a high-voltage range well below the isodose curve.

Many television receivers contain a high-voltage protection circuit, which switches off normal television receiver operation during faulty conditions, z. B. when the anode high voltage reaches values that lead to operation in the range above the isodose curve would lead. For this purpose, a return voltage pulse applied to a secondary winding of a Flyback transformer is generated, rectified and filtered and then a comparator as one for the Anode high voltage representative input voltage can be applied. If the anode high voltage represented by the input voltage has one exceeds a predetermined trigger value, the comparator generates a shutdown signal, which is used to switch off the normal television receiver operation is used.

Since the amount of X-ray radiation is a function of both the beam current of the picture tube and the value of the ultor voltage, the should be the protective circuit set pre-determined tripping value the ultor voltage change with the value of the beam current. A circuit that takes this into account is known from US-PS 42 13 16b. A DC voltage derived from the flyback transformer is applied here Given a voltage divider, to whose lower partial resistance a transistor is connected in parallel, whose Opposition changed depending on the beam current will. As the beam current increases, the divider ratio and thus the tap voltage increase, see above that the Ab'-elui'isigpal for d.c protection circuit at lower A'K> denspanniingcn is generated. At low Striihlströmcn n.'agier; Before protection circuit therefore less sensitive to increases in anode voltage, so that the television receiver dam: not unnecessarily is switched off. Audi in the older DE-C) S 31 04 701 is the dependence of the trigger voltage for the high-voltage shutdown on the anode high voltage and depending on the jet current, in that a negative feedback branch is created when an overcurrent occurs a Ves amplifying transistor is separated, so that its gain for a beam current-dependent input signal becomes larger and smaller current increases above this limit value already a larger one Contribution to having a reference value for tripping

ίο supply the voltage compared to the shutdown than at current below the limit value.

From DE-AS 29 05 005 a beam current limiting circuit is known, with different time constants to differentiate the mean beam current of peak jet current are discussed. The circuit works with a normally low beam current larger time constant, so that here short-term peaks are not as fast as with permanently higher beam current be limited. A diode is used to switch the time constant, which is activated when the mean beam current is higher is blocked and an additional / integration capacitor makes ineffective.

From US-PS 41 26 816 it is also known to tap a winding of the flyback transformer lying voltage divider cinzukoppeln a beam current-dependent signal, so that to trigger the protective circuit (blocking of the line oscillator) with a higher beam current already a lower anode high voltage enough. The twofold dependence of the triggering of the protective circuit on anode high voltage and jet stream is also known from US Pat. No. 4,045,742.

The known circuits have the tendency to reproduce even when in normal operation Switch off short-term high-voltage peaks that occur, for example when changing channels or when the transition from a relatively bright to a relatively dark scene occur where by a sudden Reduction of the beam current as a result of the corresponding relief of the high-voltage generator, the anode voltage can briefly assume high values, which by no means switch off the playback justify because they are only temporary.

In contrast, the object of the invention is a high-voltage protection circuit in which the trigger voltage for the interruption of the high voltage generation of the size of the beam current depends, in the specification of measures, that a shutdown only with long-lasting strong beam current allow, so that unnecessary shutdowns are avoided.

This object is achieved by the characterizing features of claim 1.

The solution principle of the invention makes use of two integrators with different Time constants use, from which the integrator with the longer line constant over a switching element the integrator with the shorter time constant

bo is coupled, so that at low beam currents only the Integrator with the shorter time constant is effective, while at higher beam currents the at one than Switch used diode applied voltage itself so vcranden. that the diode is conductive and the Integrate gate with the slower time constant. This gives the filter, with the help of which the vom Beam current dependent measurement voltage component is derived, the lazy time constant, so that only

Long-term, but not short-term overload conditions can affect a shutdown. on this way, unnecessary shutdowns of the receiver due to normal operation are entirely avoided possible conditions prevented so that the receiver does not unnecessarily switch off and the viewer forcing it to be switched on again.

Further developments of the invention are characterized in the subclaims.

To enable the predetermined value of the ultor voltage at which a switch-off signal is generated, changes with the beam current load, can also be connected to an input of the comparator apply a voltage characteristic of the beam current. Such tension can be derived from that Voltage obtained at the entrance of the jet current limiter of the television receiver is developed, and can then be applied to the comparator after filtering will. In addition, you can provide an overcurrent sensing circuit that the comparator for output a shutdown signal when an overcurrent condition exists such as B. in the event of a failure of the kinescope driver circuit, a short circuit between a picture tube electrode and ground or a short circuit between individual electrodes such as between grid and cathode.

In the invention, the characteristic for the jet current Voltage that is applied to the comparator of the protection circuit, filtered so that the filtered Voltage does not activate the comparator if there are sudden but normal changes in the beam current values, such as B. during a channel change or during a change in the displayed image from a relatively bright to a relatively dark scene or also with temporary or brief flashovers on the picture tube while on the other hand, however, an activation of the comparator under permanent or long-lasting overcurrent conditions he follows.

According to the invention, the beam current filter for the input signal of the comparator contains two voltage-integrating Networks of different time constants. The first voltage integrating network is effective for generating the filter output voltage if the time integral is that for the beam current characteristic stress lies within a first range of values, and the second stress-integrating Network becomes effective for generating the filter output voltage when said voltage is within another range of values

The cell constant of the first voltage-integrating According to the invention, the network is chosen to be small enough to prevent the comparator from emitting a switch-off signal returns when the beam current load is under normal television viewing conditions changes abruptly from a lower to a higher value On the other hand, the time constant of the second voltage-integrating network is chosen long enough to prevent the filter output voltage from increasing changes significantly during a temporary overturn on the picture tube.

According to a preferred embodiment of the invention contains a shutdown arrangement for a television receiver a high voltage generator for generating a picture tube ultor voltage and Means for generating a voltage representative of the ultor voltage and one Voltage representative of the kinescope beam current. A filter contains a first voltage-integrating element Device and a second voltage-integrating device whose time constant is longer than that Time constant of the first voltage-integrating device. The voltage representative of the beam current is applied to the filter in order to generate a filter output voltage which is characteristic of the time integral is the voltage representative of the beam current. The first voltage integrating device

lü becomes the formation of the time-integrated voltage effective when the time integral of the voltage characteristic of the beam current is within a certain Range of values. With the second voltage integral, which has the longer time constant is! means coupled to activate this voltage integrator when the time integral the voltage representative of the beam current is within a different range of values that indicate a beam current overload condition causing the shutdown of normal operation of the television picture display device requires. The second voltage integrator forms the time integral of the voltage as soon as it is activated. The one for the ultor voltage representative voltage and the filter output voltage are applied to a comparator, which outputs a switch-off signal generated when the ultor voltage exceeds an amount that at different values the filter output voltage is different in each case. The shutdown signal is used to switch off the normal Switch off operation of the television picture display device.

In a particular embodiment of the invention, the first voltage-integrating network contains a first capacitor, and the second voltage-integrating network contains a second capacitor and a device for coupling the second capacitor in parallel with the first capacitor when the voltage across the first capacitor exceeds a predetermined amount. Such a coupling device can, for. B. can be realized by connecting a diode in series with the second capacitor and connecting this series circuit in parallel with the first capacitor.
According to another embodiment, it is

ensures that the protection circuit can sense an overcurrent condition. This is achieved in that the Filter output voltage via a variable impedance is applied to the comparator. The impedance has a first value when the filter output voltage is below a predetermined amount and it has a second value when the filter output voltage is above the predetermined amount. The changeable impedance can e.g. B. by a parallel connection a resistor with a zener diode.

The invention is explained below using an exemplary embodiment with reference to a drawing thereof The only figure shows a deflection and high-voltage generator for a television picture display device Contains circuit arrangement according to the invention for switching off the high voltage

According to the drawing, an AC supply voltage (mains voltage) from a source 20 to the Input terminals 22 and 23 of a full wave bridge rectifier 26 placed between the AC voltage source 20 and the input terminal 22 there is a mechanical on / off switch (power switch of the television receiver) 21. Between an output terminal 24 and the ground connection 25 of the bridge

rectifier 26 is a smoothing capacitor 27 connected. A smoothed, but unregulated single input voltage Vi appears at terminal 24.

The terminal 24 is connected to a conventional voltage regulator 28 to generate a ^r regulated (stabilized) DC supply voltage B + at a terminal 29th The voltage regulator 28 can be, for example, a regulator which operates in switching mode with a thyristor and which is operated with the horizontal deflection frequency MTu. A filter capacitor 30 is connected between terminal 29 and ground in order to filter out the horizontal frequency ripple from the regulated voltage. The filter capacitor 30 can have a relatively small capacitance value compared to the line voltage smoothing capacitor 27. The supply voltage β + generated at the terminal 29 reaches a horizontal deflection generator 33 via the primary winding 31a of a flyback transformer 31 in order to supply it with energy. The horizontal deflection generator consists of a series connection of a trace or S-shaping capacitor 34 with a horizontal deflection winding 35, a flyback capacitor 36, a line diode 37 and a horizontal output transistor 38, which is controlled by a horizontal frequency switching signal, which comes from a horizontal oscillator 41, by a Horizontal driver transistor 40 is amplified and coupled to the horizontal output transistor 38 via a driver transformer 39. The collector supply voltage for the driver transistor 40 is guided from the terminal 29 via a resistor 42 that. A filter capacitor 43 is connected to the connection point between the resistor 42 and the primary winding of the driver transformer 39.

The horizontal deflection generator 33 and the flyback transformer 31 form a system for generating a high voltage and an auxiliary DC supply voltage. During normal operation of the horizontal deflection generator 33, the return pulse voltage V _r developed at the collector of the horizontal end transistor 38 is applied as an excitation voltage to the primary winding 31a of the flyback transformer in order to generate flyback pulse voltages at the output windings 31 i> to 31 e of the flyback transformer. The output winding 31d of the flyback transformer is a three-section high voltage winding. The return pulse voltages developing at the three sections are rectified by respective diodes 15 to 17 and filtered by a capacitor 18 in order to generate a terminal anode direct voltage, i.e. the acceleration potential for the beam current, at a terminal U which is connected to the terminal anode of the picture tube Television receiver is connected (not shown). The filter capacitor 18 can be formed by the capacitance between the inner and the outer conductive coating of the envelope of the picture tube.

The one on winding 316 of the flyback transformer The developed voltage is rectified via diode 53 during the retrace interval of the deflection cycle and filtered by a capacitor 54 to provide an auxiliary DC supply voltage at a terminal 55 of e.g. + 210VoIt. This supply voltage supplies various load circuits of the television receiver such. B. the kinescope driver circuits not shown in the figure) with energy. b5 The one at the output winding 31c of the flyback transformer Voltage developed by diode 44 during the trace interval of a deflection cycle rectified and filtered by a capacitor 45 to provide an auxiliary DC supply voltage at a terminal 46 of for example +24 volts. This DC voltage supplies other circuits of the television receiver such. B. the sound channel and the vertical deflection circuit (neither in the figure shown).

During stationary operation of the television receiver, a diode 47 is forward-biased in order to apply the +24 volt voltage developed at terminal 46 to a terminal A for supplying energy to the horizontal oscillator 41. During the start-up operation of the television receiver immediately after the initial streaking of the mechanical power switch 21, there is no voltage at connection A of the horizontal oscillator 41.

A start-up supply source 60 is coupled to the terminal A in order to apply a start-up supply voltage to the horizontal oscillator 41. The unregulated DC input voltage V developed after the mechanical mains switch 41 has been closed at terminal 24 is applied to voltage regulator 28 in order to develop voltage at S * -F.input terminal 29. The voltage V, is also applied to the base of a starting transistor 49 via a resistor 50, which is part of a voltage divider formed from the resistors 50 and 51, and is also applied to the collector of this transistor via a resistor 48. A blocking voltage protection diode 52 is connected between the base and emitter of the transistor 49.

During the start-up of the television receiver, the input DC voltage V, biases the transistor 49 on so that it conducts current from the terminal 24 to the terminal A and from there to the horizontal oscillator 41 in order to start and maintain the operation of the horizontal oscillator during the start-up interval . Diode 47 is reverse biased to prevent current from transistor 49 from being shunted to oscillator 41 to any other load.

When the horizontal oscillator 41 becomes effective, the horizontal output transistor 38 begins its switching operation required to generate the flyback pulse voltage V _r. As soon as the flyback pulse voltage V _{r is} developed, DC voltages are generated at the auxiliary supply terminals 46 and 55 in order to supply power to the various load circuits of the television receiver connected thereto.

The voltage developed by the start-up energy source 60 during the start-up interval at the emitter of the transistor 49 is selected to be large enough to cause the horizontal oscillator 41 to start oscillating, but it is less than the DC voltage which is developed at the terminal 46 as soon as it is developed stationary operation sets in. During stationary operation, the diode 47 is biased in the forward direction and applies the +24 volt DC voltage to terminal A and to the emitter of the starting transistor 49. The transistor 49 is biased during steady-state operation of the television receiver, which causes the start-up -Source of supply 60 becomes ineffective.

A high voltage cut-off device 61 senses the ultor voltage by sensing the one representative thereof Flyback pulse voltage 64 at the output winding 31 e of the flyback transformer and supplies a switch-off signal to the collector of a comparator transistor 62. This transistor 62 and a transistor

stor 63 form a latch or hold circuit 99 whose output via a diode 89 and a resistor 95 is connected to the base of the horizontal driver transistor 40 of the horizontal deflection generator 33. That developed at the collector of the comparator transistor 62 Shutdown signal is used to activate hold circuit 99 to operate normal TV playback mode switches off.

The flyback pulse voltage 64 generated at the winding 31e of the flyback transformer is determined by voltage dividing resistors 65 and 66 and divided by a resistor 67, a diode 68 and a capacitor 69 rectified and filtered and then one of the resistors 70 and 71 via a resistor 70 The voltage divider formed is applied to the emitter input electrode of the comparator transistor 62. The on a comparator input terminal 98 developed voltage Vi is across a resistor 77 to the Base electrode of comparator transistor 62 coupled. A diode 74 is connected to the base of the transistor on the anode side 62 and connected on the cathode side to the emitter of this transistor.

During normal operation of the television receiver, the amplitude of the flyback pulse voltage 64 is low enough that the voltage Vb at the comparator input terminal 98 can forward bias the diode 74 to conduct, so that the comparator transistor 62 is kept off. In the event of a malfunction such as B. when operating the television receiver with a faulty voltage regulator, the ultor voltage can increase to undesirably high values. The undesirable increase in ultor voltage is felt as an increase in the amplitude of flyback pulse voltage 64. If the ultor voltage has risen above a predetermined threshold value, above which a shutdown of normal television receiver operation is desirable, the emitter voltage of the comparator transistor 62 is so much higher than the voltage Vi at the comparator input 98 that the diode 74 in the reverse direction and the transistor 62 is tensioned on passage. The collector current from transistor 62 turns on transistor 63, thereby energizing hold circuit 99.

The current coming from the emitter of the transistor 63 flows to the base of the horizontal driver transistor 40 and keeps this transistor continuously conductive as long as the holding circuit 99 is activated. If the horizontal driver transistor 40 is continuously conductive, the base of the horizontal end transistor 38 receives no input signal, so that the horizontal deflection generator 33 is ineffective. A flyback pulse voltage Vr is no longer developed and applied to the primary winding 31a of the flyback transformer, and flyback pulse voltages are no longer generated at the high-voltage winding 3id , so that the ultor voltage from terminal U disappears

If the horizontal deflection generator 33 is switched off by the switch-off device 61, the return pulse saving 64 on the transformer winding 31e also disappears. In order to ensure that the television receiver operation is switched off once the switch-off device 61 has been activated, a maintenance current for the holding circuit 99 is supplied at the emitter of the comparator transistor 62 from the terminal A via a resistor 72 and a diode 73, even if the retrace pulse voltage 64 decreases when the horizontal deflection generator 33 is switched off, the holding circuit 99 remains energized by the maintenance current flowing from the terminal A. FIG. The maintenance current at terminal A comes from the running supply circuit 60, which becomes effective again after the voltage at the supply terminal 46 has become zero, due to the lack of flyback pulse voltages on the secondary winding 31c of the flyback transformer.

H) The disconnection device 61 can be made ineffective by opening the mechanical power switch 21 will. When the smoothing capacitor 27 has discharged so far that it does not have sufficient maintenance current can deliver more, the holding circuits 99 and the cut-off device 61 are de-energized. When the power switch 21 is closed again, if the abnormal television receiver operation does not return, normal television receiver operation resumed.

A capacitor 75 is connected between the base and emitter of the transistor 62, and between the base and A capacitor 87 is connected to the emitter of transistor 63 in order to prevent loop currents flowing via ground and RF couplings during temporary picture tube flashovers, the hold circuit 99 erroneously irritate. A resistor 88 connected between the base and emitter of transistor 63 ensures that the Capacitor 87 is discharged during normal operating conditions.

The threshold value of the ultor voltage, beyond which activation of the disconnection device 61 is desired under fault conditions, is a function of the beam current drawn from the ultor terminal U. Since the generation of X-ray

j5 rays depends on the beam current strength is for it ensured that the cut-off device 61 for increases in the ultor voltage at high beam current values reacts more sensitively than at low beam current values. This is achieved by the fact that one voltage at the comparator input 98 can be changed depending on changes in the beam current value.

Two voltages are applied to the comparator input 98. The first is a reference _voltage V rC f developed across a Zener diode 90, which is applied to terminal 98 via a resistor 76. A bridging capacitor 91 is connected in parallel with the Zener diode 90. The second voltage is a voltage which is characteristic of the beam current and which is developed at a terminal D at the output of a beam current filter 82. The output voltage of this filter is coupled to the input terminal 98 of the comparator via a variable impedance 80, which consists of the parallel connection of a resistor 78 and a Zener diode 81

The beam current filter 82 contains a resistor 79 between the terminal D and a terminal BC and a voltage-integrating capacitor 83 as well as a series circuit of a second voltage-integrating capacitor 84 and a diode 85 lying parallel to the capacitor 83. A resistor 86 is also connected in parallel with the capacitor 84 terminal BC is connected to the input of a conventional Strahibegrenzerschaltung 56 at the junction of two voltage divider resistors 596 and coupled 5Sa the DC path for the current flowing from the ultor terminal U beam current passes from the terminal ÖCüber a resistor 58 to the lower end of the output winding 31c /. Between the lower end of the

Output winding 13c / and ground is a bypass capacitor 57 for horizontal frequency components

The voltage at terminal BC is a function of the beam current drawn from terminal U; an increase in the beam current leads to a decrease in the voltage developed at the terminal SC. The beam current limiter 56 responds to the voltage developed at terminal BC , representative of the beam current, and operates in a conventional manner to control the maximum beam current that is drawn under normal operating conditions at high brightness values.

The beam current filter 82 has a first and a second voltage-integrating circuit with different integration time constants. The first voltage integrating circuit is formed by the capacitor 83 and the resistors 59 and 79. In normal Sirahlstrombelastung the filter output voltage at terminal D is developed across the capacitor 83 and represents the time integral of the representative of the beam current voltage is at terminal BC. In normal beam current loading Lung the Zcitintcgral or the filter output voltage remains at the terminal D is above zero, that the diode 85 is biased in the reverse direction. By blocking the diode 85, a second voltage-integrating circuit, which consists of the capacitor 84 and the resistor 86, is decoupled from the terminal D.

The filter output voltage developed at terminal D is damped by the resistor 78 of the variable impedance 80 and applied to the comparator input 98 in order to change the response sensitivity of the switch-off device 61 as a function of the beam current load, as indicated by the filter output voltage. A greater beam current load, for example, leads to a reduced voltage at the comparator input 98. The threshold voltage which the ultor voltage must exceed before the comparator transistor 62 becomes conductive is therefore lower in the state of greater beam current load. If the beam current is lower, the ultor voltage must exceed a higher threshold value before the switch-off device 61 responds, so that an erroneous switch-off of the television receiver operation at low beam current values is avoided. The comparator 62 thus generates the switch-off signal when the ultor voltage exceeds a predetermined amount which is different for different values of the filter output voltage.

In order to prevent the shutdown device 61 from responding when the television receiver is initially switched on and when the television receiver is switched off by opening the mains switch 21, the Zener diode 90 is biased from both the β ⁺ input terminal 29 and from the +210 volt -Auxiliary supply terminal 55 supplied.

During the start-up interval after the mains switch 21 has been closed, voltage develops at the β ⁺ input terminal 29. The Zener diode 90 receives a bias current via a resistor 93 and a diode 94 in order to develop the voltage V _rc r which is applied to the comparator input 98. A positive voltage is generated at the base of the comparator transistor 62 before the return pulse voltage 64 reaches a sufficiently high amplitude to render the comparator transistor 62 conductive. This prevents the switch-off device 61 from being erroneously activated.

During the stationary, normal television receiver operation, after the +210 volt voltage has set, the Zener diode 90 receives its bias current from the terminal 55 via a resistor 9'2. ι DichL- additional pre-power supply from terminal 55 is required when the power switch 21 has been opened to turn off the television receiver. When the television receiver is switched off, the voltage at the B * terminal 29 drops rapidly because of the relatively low capacitance value of the filter capacitor 30. In contrast, the voltage at the +210 vol supply terminal 55 does not decrease as quickly. Thus, bias current for the Zener diode 90 flows from the terminal 55 to ensure that a positive voltage is applied to the base electrode of the comparator transistor 62 while the television receiver is switched off, even if the S * terminal 29 has become dead and is therefore not used as a bias current source. The load circuits connected to the auxiliary supply terminal 55 in the television receiver form an overall sufficiently low load that the base voltage of the comparison transistor 62 decays more slowly than the emitter voltage when the television receiver is switched off. In this way, incorrect activation of the switch-off device 61 while the television receiver is being switched off is avoided.

Some television receivers contain picture blanking circuits in order to blank out the picture display on the picture tube during a channel change. If the reproduced image of the previously selected channel represents a bright scene, then the channel change will lead to an abrupt change in the beam current load from a high beam current value to a blanking value or disappearance of the beam current. Because of the reduced load on the terminal anode connection U during the channel change, the amplitude of the return pulses rises relatively suddenly to the high idle value. This sudden appearance of the high idle amplitude of the return pulses manifests itself as a correspondingly sudden increase in the voltage at the emitter of the comparator transistor 62. In order to prevent the comparator 62 from incorrectly developing a switch-off signal in the event of relatively abrupt changes in the beam current, which can occur in normal television playback mode, the beam current filter is used 82 designed so that the voltage at the comparator input 98 can also rise relatively quickly when the beam current load changes from a high to a low value. The time constant assigned to the capacitor 83 of the first voltage integrating circuit is selected to be sufficiently small so that the voltage Vi at the comparator input can follow the increase in the emitter voltage of the comparator caused by the disappearance of the load on the terminal anode connection U. Typically, a time constant of a few milliseconds is sufficient to prevent the television receiver from being switched off incorrectly during a channel change or a scene change if a relatively long-lasting bright scene is suddenly replaced by a relatively long-lasting less bright scene.

On the other hand, the time constant of the first integrating circuit of the beam current filter 82 must not be made too low, since it is desirable to filter out the normal higher-frequency voltage changes from the voltage developed at terminal D , which are caused at terminal BC by typical differences in brightness in the scene content, e.g. B. between one area of a grid and another

Area of the same grid or when alphanumeric characters are displayed on the screen. A filtering out This jet stream walls are advisable in order to prevent those associated with the higher sacredness Sections of the beam current reduce the voltage Vj, at the comparator input 98 so far that the comparator 62 is switched on during the normal "bright" sections of the beam current changes.

The variable impedance 80 gives the cut-off device 61 the possibility of an overcurrent cut-off in order to make the deflection generator 33 ineffective in the event of permanent or long-lasting beam current overload conditions. Such a permanent overload condition can occur when an electrode of the picture tube is short-circuited to ground or to another picture tube electrode, e.g. B. in the event of a short circuit between the grid and cathode of the picture tube, or if a failure of the video driver circuit leads to the cathode of the picture tube being overdriven.
. In the event of an overload condition, the output voltage of the beam current filter at terminal D is significantly reduced. The voltage applied across the variable impedance 80 is high enough to allow the Zener diode 81 to conduct in breakdown mode and to apply the filter output voltage to the terminal D directly to the comparator input 98 without attenuation. If the beam current exceeds a predetermined level for a relatively long duration, which indicates a permanent overload condition, and if the Zener diode 81 conducts in breakdown mode, the comparator transistor 62 is forward-biased, practically independently of the voltage developed at the emitter electrode of the comparator transistor and thus practically independent of the value of the ultor voltage and thus practically independent of the value of the ultor voltage. In order to provide this possibility of overcurrent shutdown, the variable impedance is designed so that it has a higher impedance value when the beam current load is relatively low and that it has a lower impedance value when the beam current is relatively high for a long time.

In the event of a temporary or brief flashover on the picture tube, which typically lasts a few tens of milliseconds, the beam current load increases considerably. Such a short-term high beam current load is generally undesirable, but does not last so long that normal receiver operation would have to be switched off. It is therefore v. It is undesirable to design the disconnection device 61 in such a way that, although it responds to long-term overcurrent conditions, it does not respond to brief overcurrent conditions. If the beam current filter 82 only had a relatively short integration time constant, then the filter would not be able to filter out the voltage changes at the terminal D caused by brief picture tube flashovers. The disconnection device 61 would then be erroneously activated by brief picture tube flashovers.

To avoid this, it is ensured that the cut-off device 61 on the one hand can take effect in the event of prolonged overload conditions, on the other hand but does not respond to brief overload conditions. The jet stream feeder 82 contains this Purpose of a second voltage isolationcndc circuit comprising a capacitor 84 and a Vv idcrstand 86 and through a diode 85 from the first voltage integrating one formed with the capacitor 83 Circuit is decoupled

In the case of a long-term high beam current load, the first voltage-integrating circuit integrates the voltage appearing at the terminal BC and characteristic of the beam current into a voltage on the capacitor 83 which has a lower value than the integrated voltages which are developed under a medium or low beam current load. When the jet current load is strong enough and sufficient

ίο lasts a long time, then the voltage at the terminal D becomes negative, whereby the diode 85 is spanfit in the forward direction and the capacitor 84 couples in parallel to the capacitor 83. The capacitance value of the capacitor 84 is selected to be much larger than the value of the capacitor 83. Therefore, in the case of a high beam current load, if the diode 85 is forward biased. the capacitance value of the second integrating circuit is essentially determined by the value of the capacitor 84. The time constant of the second integrating circuit is dimensioned to be much larger than the time constant of the first integrating circuit, e.g. B. on the order of a few hundred milliseconds.

After the second voltage integrating circuit ceases to operate after the diode has turned on Once it has begun, it continues with the integration of the characteristic of the strong, long-lasting Sirahlstrom Tension continues. The value of the relatively large time constant of the second voltage-integrating The circuit is chosen so that brief or temporary picture tube flashovers are integrated and are not able to use your filter output voltage at the terminal to generate, which is more negative than a diode voltage drop below the ground potential.

A filter output voltage that is the value of a diode voltage drop below ground potential is not sufficient to drive the Zener diode 81 into the breakdown and to activate the switch-off device 61.

For example, if the strong, persistent overload condition lasts for a few hundred milliseconds, what indicates a long-term overload condition, then the second voltage integrating circuit has enough time to produce a voltage across capacitor 84 that is negative enough to cause the To allow the Zener diode 81 to break through in the reverse direction and to activate the disconnection device 61. The parallel Resistor 86 connected to capacitor 84 discharges the capacitor when the overload condition clears or after the television receiver has switched off.

In other words, the time constant of the filter 82 is relatively small for a relatively low beam current load and becomes relatively large in the case of a high jet current load

made to determine the existence of a permanent overcurrent condition. If such a strong Overload is sensed, the hold circuit 99 is energized to shut off normal television viewing.

1 sheet of drawings

Claims (1)

Patent claims: 1. Circuit arrangement for switching off a television receiver in the event of excessive anode high voltage depending on the beam current of the picture tube, - with a high voltage generator to generate the anode high voltage, - with a measuring voltage circuit for generation a first measurement voltage as a measure for the anode high voltage, - with a jet current sensing circuit generating a second measuring voltage as a measure for the Sirahlstrom, which contains an integrating filter and a switch dependent on the beam current, - With a comparison circuit for comparing the two measurement voltages with a reference voltage and generation of a switch-off signal when the reference voltage is exceeded, - and with an interrupter circuit for the high voltage generation triggered by the switch-off signal,